Minimum Spanning Trees CS 146 Prof. Sin-Min Lee Regina Wang.
Yang Wang, Prof. Kincho H. Law
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Transcript of Yang Wang, Prof. Kincho H. Law
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Design of a Low-Power Wireless Structural Monitoring System for
Collaborative Computational Algorithms
Yang Wang, Prof. Kincho H. Law
Department of Civil and Environmental Engineering, Stanford University
Prof. Jerome P. Lynch
Department of Civil and Environmental Engineering, University of Michigan
SPIE, San Diego, CA, March 6, 2005
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AgendaAgenda
Research background Hardware design of the latest wireless
sensing unit prototype Software design of the latest wireless SHM
system Large-scale field validation tests Future direction
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AgendaAgenda
Research background Hardware design of the latest wireless
sensing unit prototype Software design of the latest wireless SHM
system Large-scale field validation tests Future direction
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Structural Health Monitoring (SHM)Structural Health Monitoring (SHM)
S. Chase (2001), NBIP Report: Nearly 60,000 bridges in U.S. evaluated as structurally deficient.
Over 580,000 highway bridges in U.S. mandated for biannual evaluations.
Advanced Sensing Technology for Autonomous SHM:
Rapid, accurate, low-cost
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From Wire-based Sensing to Wireless SensingFrom Wire-based Sensing to Wireless Sensing
E. G. Straser, and A. S. Kiremidjian (1998): Installation of wired system can take about 75% of testing timeM. Celebi (2002): Each sensor channel and data recording system: $2,000; Installation (cabling, labor, etc.) per wired channel: $2,000.
Traditional DAQ System: wire-based
Future Wireless DAQ System
Wireless SHM prototype system Jointly developed by researchers in Stanford University and the University of Michigan
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Challenges in Wireless Structural Sensing (1)Challenges in Wireless Structural Sensing (1)
Requirements for long-distance high-speed wireless data acquisition, and extensive local data processing
HIGHER PERFORMANCE LOWER POWER
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Challenges in Wireless Structural Sensing (2)Challenges in Wireless Structural Sensing (2)
Hardware
Restricted communication range
Limited bandwidth
Unreliable wireless transmission
Software
Difficulty for data synchronization
Difficulty for robust communication design
Background → Sensing → Control → Summary
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Dr. E. G. Straser, Prof. A. Kiremidjian (1998)
Dr. J. P. Lynch, Prof. K. H. Law et al. (2002)
Y. Wang, Prof. J. P. Lynch, Prof. K. H. Law (2005)
Wireless SHM Unit Prototypes from Stanford and UMichWireless SHM Unit Prototypes from Stanford and UMich
L. Mastroleon, Prof. A. Kiremidjian et al (2004)
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AgendaAgenda
Research background Hardware design of the latest wireless
sensing unit prototype Software design of the latest wireless SHM
system Large-scale field validation tests Future direction
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Picture of the Prototype with Wireless ModemPicture of the Prototype with Wireless Modem
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Atmega128 Micro-
controller
Sensor Connector
4 Channel, 16-bit A2D Converter
Address Latch for the External
Memory
128kB External Memory
Power Switch
Connector to Wireless Modem
Prototype Double-layer Circuitry BoardPrototype Double-layer Circuitry Board
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Container Dimension
4.02” x 2.56” x 1.57”
(10.2cm x 6.5cm x 4.0cm)
Antenna Length: 5.79” (14.7cm)
Wireless Sensing Unit Prototype PackageWireless Sensing Unit Prototype Package
Power supply requirement: 5.2V
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Power consumption: 75 – 80mA when active; 0.1mA standby
Communication range: 90m indoor, 300m outdoor
16bit Analog-To-Digital conversion, 4 A2D channels
Local data processing
Point-to-multipoint, and peer-to-peer communication
Low hardware cost
Hardware Performance SummaryHardware Performance Summary
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AgendaAgenda
Research background Hardware design of the latest wireless
sensing unit prototype Software design of the latest wireless SHM
system Large-scale field validation tests Future direction
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Wireless Sensing NetworkWireless Sensing Network
Prototype system: simple star topology network
Firmware for wireless sensing units
Server-side computer software
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Reliable Beacon Signal Synchronization ProtocolReliable Beacon Signal Synchronization Protocol
BroadcastBeacon signal to
all WSUs Begin sensor datasampling and
storage
Verify with eachWSU if it
received theBeacon signal
A WSU didn't receivethe Beacon signal
Inform WSUs* oneby one to restart
* WSU: Wireless Sensing Unit** CS: Central Server
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Receivedbeacon signal
Wait andRespond to
Beaconverification
Restart andacknowledge with
CS**, wait forBeacon signal
Wait for datacollection
command from CS
Receive restartcommand
Y
Start data collection fromWSUs one by one, and
round by roundTransmit data to
CS
Received datacollection request and
data is ready
Central Server Wireless Sensing Unit
Finish one round ofdata transmission
Wireless communicationand its direction
Y
Y
Approximate beginningsynchroni zation
preci sion: 20 micro-Seconds.
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AgendaAgenda
Research background Hardware design of the latest wireless
sensing unit prototype Software design of the latest wireless SHM
system Large-scale field validation tests Future direction
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Geumdang Bridge Test, KoreaGeumdang Bridge Test, Korea
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NORTH
Pier Pier PierAbutment
46.0m18.7m 18.7m
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Bridge Traffic ExcitationBridge Traffic Excitation
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Sensor PropertyPCB Piezoelectric
(Cable System)PCB MEMS Capacitive
(Wireless System)
Maximum Range 1 g 3 g
Sensitivity 10 V/g 0.7 V/g
Bandwidth 2000 Hz 80 Hz
RMS Resolution (Noise Floor) 50 g 0.5 mg
Wire-based System versus Wireless SystemWire-based System versus Wireless System
Sampling Frequency 200Hz 70Hz
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155 160 165 170 175 180 185 190-0.04
-0.02
0
0.02
0.04KAIST Data Aquisition System
Time (sec)
Acc
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n (g
)Sensor Location #8
155 160 165 170 175 180 185 190-0.04
-0.02
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0.02
0.04Wireless Data Aquisition System
Time (sec)
Acc
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n (g
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Sensor Location #8
Time History Comparison Between Two SystemsTime History Comparison Between Two Systems
Wireless System
Wire-based System
Difference in sensors and signal conditioning
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0 2 4 6 8 10 12 14 160
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FFT - KAIST DAQ
Frequency (Hz)
Mag
nitu
de
Sensor Location #8
0 2 4 6 8 10 12 14 160
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FFT - Wireless DAQ
Frequency (Hz)
Mag
nitu
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Sensor Location #8
Comparison of FFT ResultsComparison of FFT Results
Wireless System
Wire-based System
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Validation Results SummaryValidation Results Summary
Rapid installation, and low cost
Communication range: 50 – 60m in box girder
Networked real-time and non-stopping data collection: up to 24 wireless sensors at 50Hz sampling frequency
Data is near-synchronized: modal analysis
Local data processing capability: 4096-pt FFT by wireless sensing unit
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AgendaAgenda
Research background Hardware design of the latest wireless
sensing unit prototype Software design of the latest wireless SHM
system Lab validation tests Large-scale field validation tests Future direction
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Future DirectionFuture Direction
To be improved for current prototype system:
Sensor signal conditioning
Greater wireless communication range, higher data rate
Large-scale data collection from densely allocated sensors
Local data analysis and damage identification algorithm
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AcknowledgementAcknowledgement
National Science Foundation CMS-9988909 and CMS-0421180
The Office of Technology Licensing Stanford Graduate Fellowship
The University of Michigan Rackham Grant and Fellowship Program
Prof. Chung Bang Yun, Prof. Jin Hak Yi, and Mr. Chang Geun Lee, at the Korea Advanced Institute of Science and Technology (KAIST)
Prof. Law, Prof. Kiremidjian and Prof. Miranda
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The EndThe End